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Drugs Affecting the Autonomic Nervous System-3
Cholinergic AntagonistsAssistant Prof. Dr. Najlaa Saadi
PhD PharmacologyFaculty of Pharmacy
University of Philadelphia
The cholinergic antagonists (also called cholinergic blockers, parasympatholytics or anticholinergic drugs)
Bind to cholinoceptors, but they do not trigger the usual receptor-mediated intracellular effects.
The most useful of these agents selectively block muscarinic synapses of the parasympathetic nerves
Cholinergic antagonist classified into: Antimuscarinic Agents:
• M1 Selective.• Non selective.
Antinicotinic Agents:• Ganglionic Blocking Agents. • Neuromuscular Blocking Agents.
Antimuscarinic Agents Tertiary amine
(Alkaloid esters of tropic acid)• Atropine: (prototype)• Hemoatropine:• Scopolamine.
Quaternary amine(Semi synthetic & synthetic)Produce more peripheral effects with decrease CNS effect.• Propantheline• Ipratropium• Clidinium bromide.
Sites of Actions of Cholinergic Antagonists
Antimuscarinic AgentsTertiary amineAtropine A tertiary amine belladonna alkaloid Acts both centrally and peripherally It has a high affinity for muscarinic receptors,
binds competitively & reversiblely,preventingAch from binding to that site.
Block muscarinic receptors causing inhibition of all muscarinic functions.
Block the few exceptional sympathetic neurons that are cholinergic, such as those innervating salivary and sweat glands.
Have little or no action at skeletal neuromuscular junctions or autonomic ganglia (because they do not block nicotinic receptors).
Its general actions last about 4 hours except when placed topically in the eye, where the action may last for days
Note: A number of antihistaminic and antidepressant drugs also have antimuscarinic activity.
ActionsEye Dilates the pupil (mydriasis). Cycloplegia ,Light enter freely and the normal
pupillary reflex accommodation is paralyzed (cycloplegia) and the lens is fixed for far vision.
Increase intraocular pressure Decrease lachrymal secreation (sandy eyes)
Gastrointestinal (GI) Atropine and scopolamine can be used as
an antispasmodic to reduce activity of the GI tract.
The drug is not effective in promoting healing of peptic ulcer hydrochloric acid production (is not significantly affected).
Urinary system Atropine reduce hypermotility states of
the urinary bladder. It is still occasionally used in enuresis (involuntary voiding of urine) among children
Note: α-adrenergic agonists with fewer side effects may be more effective
Respiratory Bronchial dilatation Decrease secretion
Cardiovascular Atropine block the cardiac receptors on the SA
node so the cardiac rate increases modestly (tachycardia).
It has no significant effect on peripheral blood vessels in therapeutic dose but with poisoning, there is marked vasodilatation
Secretions Atropine blocks the salivary glands, producing a
drying effect on the oral mucous membranes (xerostomia).
Sweat and lacrimal glands are also affected.
Note: Inhibition of secretions by sweat glands can cause elevated body temperature.
CNS Has minimal stimulant effect (at normal dose)
and slow sedation
Dose-dependent effects of atropine
Pharmacokinetics of Atropine It is readily absorbed Partially metabolized by the liver, and
eliminated primarily in the urine It has a half-life of about 4 hours.
Adverse Effects (Depending on the dose) Dry mouth Blurred vision Sandy eyes Tachycardia Constipation CNS : restlessness, confusion, hallucinations,
and delirium, depression Collapse of the circulatory and respiratory
systems, and death.
In older individuals, the use of atropine to induce mydriasis and cycloplegia may cause glaucoma.
In other older individuals, atropine may induce urinary retention
Children atropine, cause rapid increases in body temperature.
Note: Low doses of cholinesterase inhibitors such as physostigmine may be used to overcome atropine toxicity
Hemoatropine: Semi syntheticScopolamine: Tertiary amine belladonna alkaloid Produces peripheral effects similar to those of
atropine Scopolamine has greater action on the CNS
(unlike with atropine, CNS effects are observed at therapeutic doses)
Longer duration of action than atropine
Clinical uses of antimuscarinic agents:Ophthalmic (Atropine (hyoscyamine), Homotropine): used in
cases that need mydriasis with cycloplagia(prolonged action ). Shorter-acting antimuscarinics (cyclopentolanteand tropicamide) have largely replaced atropine due to prolonged mydriasis observed with atropine (7-14 days versus 6-24 hours with other agents).
Antispasmodic: Atropine is used as an antispasmodic agent to relax the GI tract and bladder.
Antidote for cholinergic agonists Atropine is used for the treatment of overdoses
of cholinesterase inhibitor insecticides and some types of mushroom poisoning
The ability of atropine to enter the central nervous system (CNS) is of particular importance.
Central nervous system disorder Parkinson's disease A number of centrally acting antimuscarinic
preparations may improve the tremor and rigidity of parkinsonism but have little effect on bradykinesia. Orpheradrine, Benztropinemesylate
Prevent or reduce motion sickness Scopolamine for seasickness ,It can be given by
injection, by mouth, or as a transdermal patch. The patch formulation produces significant blood levels over 48-72 hours
Respiratory disorder Ipratropium ,tiotropium( inhaled)for asthma
and COPD in patients unable to take adrenergic.
Tiotropium has a longer bronchodilator action and can be given once daily
Pre anesthetic injection of Atropine or Scopolamine decrease bronchial secretion ,
Scopolamine cause amnesia for events associated with surgery.
GIT Propantheline for irritable bowel syndrome ,cause
relaxation of smooth muscle (antispasmodic) Hyosine butyl bromide (Buscopan): relaxant of the
smooth muscle Scopolamine (hyoscine), promethazine: used as
antiemetic. Peptic ulcer: M1 inhibitor (Pirenzepine) Clidinium bromide: for gastric disorders,
sometimes combine with chlordiazepoxide (called librax).
Urinary Disorders Atropine and other antimuscarinic drugs used
to provide symptomatic relief in the treatment of urinary urgency caused by minor inflammatory bladder disorders. Oxybutynin, selective for M3 receptors, is used to relieve bladder spasm after urologic surgery, eg, prostatectomy
Summary of cholinergic antagonists
Ganglionic Blockers: Competitively block the action of acetylcholine and
similar agonists at nicotinic receptors of both parasympathetic and sympathetic autonomic ganglia.
Some members of the group also block the ion channel that is gated by the nicotinic cholinoceptor.
They have limited clinical use (due to lack of selectivity) but used in pharmacologic and physiologic research
Ganglionic nicotinic receptors, depolarizing and nondepolarizing blockade
Drugs now used as ganglion blockers are classified as nondepolarizing competitive antagonists.
Nicotine: Nicotine is available as patches, lozenges, gums, and
other forms. Patches are available for application to the skin.
The drug is absorbed and is effective in reducing the craving for nicotine in people who wish to stop smoking.
Mecamylamine: Competitive nicotinic blockade of the ganglia. Good oral absorption Duration of action is about 10 hours after a single
administration.
Trimethaphan It is the only Ganglion-blocker still in clinical use. Its poorly lipid soluble. Short-acting ganglion blocker Inactive orally and is given by intravenous infusion. Used to lower blood pressure in emergency
situations (malignant hypertension).
HexamethoniumFor management of hypertension
Neuromuscular Blockers These drugs block cholinergic transmission
between motor nerve endings and the nicotinic receptors on the neuromuscular end plate of skeletal muscle
Nondepolarizing (competitive) blockersTubocurarine (prototype agent) It has been largely replaced by other agents due
to side effects The neuromuscular blocking agents have
significantly increased the safety of anesthesia, because less anesthetic is required to produce muscle relaxation, allowing patients to recover quickly and completely after surgery.
Note: Higher doses of anesthesia may produce respiratory paralysis and cardiac depression, increasing recovery time after surgery.
Mechanism of action: At low doses: Nondepolarizing neuromuscular blocking drugs
(competitive blockers) interact with the nicotinic receptors to prevent the binding of acetylcholine (prevent depolarization of the muscle cell membrane and inhibit muscular contraction)
Their action can be overcome by administration of cholinesterase inhibitors, Anesthesiologists often employ this strategy to shorten the duration of the neuromuscular blockade.
At High Doses:Nondepolarizing blockers can block the ion channels of the end plate. This leads to further weakening of neuromuscular transmission, and it reduces the ability of acetylcholinesteraseinhibitors to reverse the actions of nondepolarizing muscle relaxants.
Mechanism of action of competitive neuromuscular blocking drugs.
Therapeutic Uses: In Anesthesia Facilitate intubation Relax skeletal muscle during surgery. Orthopedic surgery
Pharmacokinetics: Injected intravenously, (oral absorption is
minimal) Most non depolarizing agents have relatively
long half life ranging from (20 min - several hours).
Not enter cells or cross the blood-brain barrier. Many of the drugs are not metabolized. Most drug (tubocurarine, pancuronium,
mivacurium, metocurine) are excreted in the urine unchanged
Pharmacokinetics of the neuromuscular blocking drugs
Drug Interactions: Cholinesterase inhibitors Halogenated hydrocarbon anesthetics (halothane)act
to enhance neuromuscular blockade by exerting a stabilizing action at the neuromuscular junction.
Aminoglycoside antibiotics (gentamicin or tobramycin )inhibit acetylcholine release from cholinergic nerves by competing with calcium ions. They synergize with tubocurarine and other competitive blockers, enhancing the blockade.
Calcium-channel blockers: These agents may increase the neuromuscular block of tubocurarine and other competitive blockers as well as depolarizing blockers.
Depolarizing AgentsMechanism of Action: Succinylcholine attaches to the nicotinic receptor and acts like acetylcholine to depolarize the junction Unlike acetylcholine, which is destroyed by acetylcholinesterase, the depolarizing agent persists at high concentrations in the synaptic cleft, remaining attached to the receptor for a relatively longer time and providing a constant stimulation of the receptor
Therapeutic Uses: Because of its rapid onset and short duration
of action (total paralysis last up to 4 min) Succinylcholine is useful when rapid
endotracheal intubation is required during the induction of anesthesia (a rapid action is essential if aspiration of gastric contents is to be avoided during intubation).
It is also employed during electroconvulsive shock treatment.
Mechanism of action of depolarizing neuromuscular blocking drugs
Pharmacokinetics: Succinylcholine is injected intravenously. Its brief duration of action (several minutes)
results from redistribution and rapid hydrolysis by plasma cholinesterase. It therefore is usually given by continuous infusion
Adverse Effect 1. Malignant Hyperthermia When halothane is used as an anesthetic,
administration of succinylcholine has occasionally caused malignant hyperthermia (with muscular rigidity and hyperpyrexia) in genetically susceptible people This is treated by rapidly cooling the patient and by administration of dantrolene, which blocks release of Ca2+ from the sarcoplasmicreticulum of muscle cells, thus reducing heat production and relaxing muscle tone.
2. Apnea Administration of succinylcholine to a patient
who is genetically deficient in plasma cholinesterase or has an atypical form of the enzyme can lead to prolonged apnea due to paralysis of the diaphragm.
3. Hyperkalemia Succinylcholine increases potassium release
from intracellular stores. This may be particularly dangerous in burn patients or patients with massive tissue damage in which postassium is been rapidly lost from cells.
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